Unitized drilling bit



Oc 30, 19 J. L. STOCKARD, JR

UNITIZED DRILLING BIT 2 Sheets-Sheet 1 Filed March 31, 1959 INVENTOR JESSE L. STOCKARD,JR.

BY Mu), t ATTORNEYS 3,061,025 UNITIZED DRILLING BIT Jesse L. Stockard, in, Houston, Tex., assiguor, by mesne assignments, to Hughes Tool Company, Houston, Tex., a corporation of Delaware Filed Mar. 31, 1959, Ser. No. 803,110 12 Claims. (Cl. 175-412) This invention relates to drilling bits and more particularly to an improved drilling bit of the unitized type especially adapted for drilling holes in the ground such as shot holes, blast holes, grout holes, test holes, ex ploratory holes and small water holes.

Drilling bits of the unitized type 'are conventionally constructed of a plurality of cooperating bit segments, each segment having its cutting portion finished while the segments are in their individual condition and then the cooperating segments are secured together, usually by electrical welding. The primary reason for finishing the cutting portion of the bit as individual parts or separate segments is because of ease in manufacture. Particularly when dealing with bit blades of the insert type, it is an awkward procedure to try to fix the inserts on each of the blades of the bit when the individual segments are rigidly secured together. Moreover, the grinding of the cutting edge is made considerably more difiicult due to space requirements and the like. It is, therefore, highly advantageous in the manufacture of a drilling bit to be able to finish each blade as a separate unit and then subsequently secure the units together to form a unitized bit.

The term unitized as used in connection with this type of blade refers to the fact that the individual blade segments are rigidly secured together as a unit as opposed to removable type blades, such as disclosed in Hawthorne Patents 2,666,622 and 2,783,973. These patents disclose drilling bits which are made up of separate segments. The segments are mounted in a holding or clamping device and then mounted directly on the drilling collar rather than being rigidly secured together by the manufacturer prior to shipment. Stated differently, with a removable type blade bit, the segments are mounted together in fixed rigid relation by the user and shipped by the manufacturer as separate segments. A unitized type of drilling bit is initially made by the manufacturer in separate individual segments and these segments are rigidly fixed together by the manufacturer and shipped in that condition.

One significant problem encountered in the manufacture of unitized drilling bits of the type having insert type cutting blades results from the fact that when the separate segments are secured together by electrical welding, heat efiected zones are created in the shanks of the bit segments, causing the formation of extremely hard spots in the metal. The creation of these hard spots makes subsequent machining of the welded unit, such as threadcutting and the like, difficult and inaccurate. Also, the heat generated in prior art welding procedures may develop heat-affected zones in the material which are weak and would result in failure of the bit in operation. Such weak zones can be strengthened by heat treatment of the welded unit but such heat treatment is rendered 'difiicult, if not impossible, due to the melting point of the silver bond holding the inserts on the blades. The silver or silver bronze alloys melt at approximately 1100 F. to 1500 F. whereas the temperature necessary for heat treatment is 1600 F. to 1800 F. Also, the difierence in the thermal expansion and contraction of the steel of the bit and tungsten carbide would shear the silver alloy bond, should the parts be brought to this temperature.

An object of the present invention'is to provide drill- 3,061,025 Patented Oct. 30, 1962 ing bits securing the bit segments together by an electrical welding procedure, thus eliminatnig the problems noted above.

In its broadest aspect the present invention contemplates the finishing of a plurality of bit segments individually and then subsequently positioning the segments together in a shop fixture. The segments are then maohined while they are held together in the jig or fixture and a retaining ring that is expanded by heat is placed onto the unit to positively retain the segments together.

It will be readily understood that in the manufacture of drilling blades it is highly desirable to use high speed automatic equipment to perform the machining operations for purposes of economy, maximum production and the like. However, due to the accumulation of inaccuracies resulting from tool wear, material variation and operators inaccuracies and the like, the bits produced on high speed automatic equipment are not always machined within the desired tolerances required in operation. For example, most drilling bits are secured in the drilling string by a threaded connection, the lower end of which has an interior tapered thread box for receiving a cooperating threaded pin on the bit. In turning an exterior tapered thread on a one piece drilling bit by the use of high speed automatic equipment, the taper of the thread as well as the thread form can usually be made within the required tolerances. However, the axial position of the threads on the bit cannot always be accurately determined within required tolerances. With the use of a tapered thread type connection between the drilling collar and the drilling bit it is important to provide on the drilling hit an abutment means, usually in the form of an annular shoulder, for engaging the lower end of the drilling collar to thereby limit relative axial movement between the drilling collar and the drilling bit. It will be understood that the axial position of the annular shoulder or abutment means must come within rather close tolerances in order for the connection to be proper and sufficiently rigid.

Accordingly, it is another object of the present invention to provide unitized drilling bits of the type described which may be machined by the use of high speed automatic equipment, the possible inaccuracy of such equipment being compensated for by an improved procedure.

In this regard, the present invention contemplates the utilization of a shrink or sweat ring both to retain the segments together and as the abut-ment means for engag ing the lower end of the collar, in operation, to limit axial movement. More specifically, in the general procedure mentioned above, prior to the step of shrinking the retaining ring on the bit segments, a ring receiving portion is machined in the bit segments while they are held together, and subsequently the axial position of the tapered threads are gauged with respect to the ring receiving position. By employing a shrink ring of appropriate thickness the annular shoulder of the finished drilling bit, provided by the upper surface of the shrink ring, is accurately positioned axially with respect to the tapered threads. In this way, any possible inaccuracies that may result from the use of high speed automatic equipment in the turning of the tapered threads is compensated for.

The present invention also has for an object the pro, vision of a drilling bit of the unitized type embodying a retaining ring for securing together individual blade bit segments in fixed, rigid condition, under stress, such ring also serving to provide an abutment surface for engaging the lower end of a drilling collar when the drilling bit is connected in a drilling string.

Still another object of the present invention is the provision of a drilling bit of the type described which is simple and economical in manufacture and which can be easily serviced and maintained.

These and other objects of the present invention will become more apparent during the course of the following detailed description and appended claims.

The invention may best be understood with reference to the accompanying drawings wherein an illustrative embodiment is shown.

In the drawings: 7

FIGURE 1 is an elevational view of a drilling bit embodying the principles of the present invention and showing the same operatively connected with a drilling collar, the latter being illustrated in vertical section;

FIGURE 2 is a top plan view of the drilling bit with the drilling collar removed;

FIGURE 3 is a cross-sectional view taken along the line 3-3 of FIGURE 1;

FIGURE 4 is a fragmentary cross-sectional view taken along the line 44 of FIGURE 2; and

FIGURES 5-10 are "views similar to FIGURE 4 illustrating various modifications of the shrink ring which maybe utilized in the drilling bit.

Referring now more particularly to the drawings, there is shown in FIGURES 1-4 a drilling bit of the unitized type, generally indicated at 10, which embodies the principles of the present invention. In general, the bit is made up of a plurality of blade bit segments 12, 14 and 16. It will be understood that any desired number of segments may be employed although the utilization of three segments, as shown, is preferred. The segments are made of any suitable material as, for example, tool steel or the like, each segment being preferably produced by a forging operation. Each blade segment, as forged, includes an upper shank portion 17 and a lower blade portion 18. The exact configuration and method of forming the blade portion 18 of the blade bit segments form no part of the present invention. Preferably, they are constructed in accordance with the teachings of Weaver et al. Patent No. 2,894,726. In brief, the blade portion of each segment is forged so as to provide recesses 19 along the cutting edge thereof. In accordance with the teachings of the above mentioned patent, inserts 20 are subsequently positioned in the recesses and secured therein by the application of a suitable bonding agent of the type described in the aforementioned application.

The upper shank portion of each bit segment is forged in a 120 sector formation, as clearly illustrated in [FIG- URE 3. If necessary, the radial faces of the shank portion of each forging is initially ground to a desired accuracy. Next, the radial faces of the shank portion of each segment forging are drilled to form an aperture 22. As shown in FIGURE 3, one of the apertures 22 in the segment 12 has its axis perpendicular to the associated radial face while the axis of the other aperture 22 in the segment 12 has its axis extending perpendicular to the axis of the first mentioned aperture. The apertures formed in the segment 16 are positioned in a like manner. Finally, the apertures 22 in the segment 14 have their axes parallel to each other and extending at an angle of approximately 60 with respect to the associated radial faces.

The apertures 22 formed in the bit segments 12, 14 and 16 are accurately located so that three dowel pins 24 may be positioned within cooperating apertures, as shown in FIGURE 3, to retain the three segments in cooperating relation so that their shank portions define an annular member having a central opening 26 extending therethrough. It will be understood that in assembling the segments with the dowel pins 24, the segments 12 and 16 are initially secured together by inserting a dowel pin 24 within the apertures 22 formed therein which extend perpendicular to the associated radial faces. Finally, the segment 14 can be moved into position over the dowel pins 24 in the associated apertures 22 of the segments 12 and 16 by a linear movement in the direction of extent of the associated pins 24.

other.

The dowel pins 24 serve to retain the shank portions of the segments in their proper relation with respect to each other but they do not effect a sufficient securement of the segments together to permit subsequent machining without the utilization of additional securing means. For this purpose, the segments may be secured in position for purposes of machining the same together by tack welding, away from the threaded section, a suitable jig (not shown) or any other means. With the segments thus secured together, the exterior of the annular member formed by the shank portions of the segment, is formed at its upper end with a tapered thread 28. As indicated above, the formation or turning of the tapered thread 28 is preferably accomplished by mounting the segments, fixed together, on a high speed automatic machine. In addition to the tapered thread 28, a ring receiving portion is machined in the shank portions of the segments, while held together, in a position below the thread 28. This ring receiving portion preferably takes the form of an eX- terior cylindrical surface 30 of a predetermined diameter having an upwardly facing perpendicular transverse surface 32 extending from the lower end thereof.

As previously noted, with the use of high speed automatic equipment for turning the threads 28 accuracy of taper and thread form can readily be obtained. However, the axial position of the threads on the annular member formed by the shank portions of the segments can not always be accurately located. In a like manner, accuracy in the diameter of the cylindrical surface 30 can be readily achieved, but the axial position of the perpendicular transverse surface 32 does not always fall within the required tolerances of, for example, A inch.

The threads 28 provided on the annular member formed by the shank portions of the bit segments, in operation, are arranged to cooperate with interior tapered threads 34 formed in the lower end portion of a drilling collar 36. To provide a proper threaded connection between the drilling collar 36 and the drilling bit 10, the relative axial movement between the two members should be positively limited when the threads 28 and 34 are in an optimum cooperative position with respect to each To this end, the drilling collar 36 includes a lower end surface 38 which forms one abutment means for effecting this limitation of axial movement.

As noted above, because the perpendicular transverse upwardly facing surface 32 formed in the bit segments cannot always be accurately located in an axial direction with respect to the threads 28, the cooperating abutment means on the drilling bit 10 is provided by a shrink ring 40, which also serves to rigidly fix the bit segments 12, 14 and 16 together after the same have been machined on the high speed automatic equipment.

As best shown in FIGURE 4, the ring 40 includes an interior cylindrical surface 42 having a diameter which, under normal temperature conditions, is somewhat smaller than the diameter of the cylindrical surface 30. In addition, the ring 40 includes a lower perpendicular transverse surface 44 which is arranged to engage the transverse surface 32 and an upper perpendicular transverse surface 46, which, in operation, is arranged to engage the lower end surface 38 of the drilling collar so as to provide a cooperating abutment means therewith to limit relative axial movement between the drilling collar 36 and the drilling bit 10.

Prior to the fitting of the shrink ring 40 into engagement with the ring receiving portion of the annular member provided by the shank portions of the bit segments, the relative axial position of the perpendicular transverse surface 32 is determined with respect to the diameter of the tapered threads 28. This determination can be accomplished with any standard American Petroleum Institute (API) gauging procedure with the use of Standard A.P.I. gauging equipment. Once the axial distance between the surface 32 and an axial position on the tapered threads 28 of a given diameter has been determined, it is a simple matter to determine the proper axial location of the surface 46 of the shrink ring 40.

Preferably, this surface is located by choosing from a stock of shrink rings of various thicknesses and constant interior diameter, a ring having a thickness which will dispose the upper surface 46 in the proper axial location when the lower surface 44 is in engagement with the surface 32. In normal manufacturing procedure, the operator performing the gauging operation will stamp on the bit a ring code number indicating the thick ness of the ring which must be utilized with the particular drilling bit.

The shrink ring 40 is mounted in engagement with the ring receiving portion of the drilling bit 10 by heating the same to an elevated temperature to thereby expand the same and increase the interior dimension of the surface 42 so that it can be moved into engagement with the surface 39. Such heating may be effected by direct flame application or by placing the ring in a furnace. In practice it has been found that the ring should be heated to a temperature of the order of at least 900 F. up to a maximum temperature of the order of between 1600" F. and 1800 F., a specific example of a preferred temperature being 1050 F. Of course, the ring is fitted onto the ring engaging portion of the drilling bit while the segments are held together and while the ring is in a heated condition. The segments should be at room temperature. When the shrink ring is properly fitted on the drilling bit with the lower surface 44 thereof in engagement with the surface 32, and allowed to cool to room temperature, the upper abutment surface 46 will be disposed in proper axial position. This surface provides an abutment means in the form of an annular shoulder for engaging the lower end 38 of the drilling collar to insure a proper threaded connection between the drilling collar and the drilling bit.

Moreover, the shrink ring 40, when it has cooled, is under stress and serves to rigidly fix the individual segments of the drilling bit together without the necessity of subsequent electric welding. The position of the ring on the drilling bit is such that it provides an optimum securement of the segments together and in addition cooperates with the drilling collar to provide an optimum threaded securement between the latter and the drilling bit. Moreover, the shrink ring can be removed for purposes of repairing the blade portions of the segments whenthey become worn or damaged.

While the procedure described above is greatly preferred, it is also possible to utilize the shrink ring 4b as a means for securing the segments together prior to the formation of the tapered threads 28. When so employed, only one thickness size of the ring need be employed but,of course, it would become necessary to turn down the surface 46 in some instances to properly locate the abutment surface in an axial direction.

It will also be understood that the present invention is applicable to unitized bits of the blade type which are not provided with inserts as well as bits embodying rotary cutters and the like.

In FIGURES 5-10 there are shown various modifications of the cross-sectional configuration of the shrink ring that may be utilized in the drilling bit 10. In general, the various embodiments of the shrink ring shown in these figures provide upper and lower perpendicular transverse surfaces 46 and 44 similar to the surfaces 46 and 44 previously described. However, the interior surface of the ring has been modified. In FIGURE 5, the interior of the ring includes a cylindrical surface 42 having an annular groove 48 formed therein. The cylindrical surface 30 of the ring receiving portion of the drilling bit is provided with an annular ridge 50 arranged to cooperate with the annular groove 48.

In FIGURE 6, the interior surface of the ring is frustoconical and diverges upwardly, as indicated at 52. The corresponding surface of the ring receiving portion of the 6 drilling bit is frusto-conical, as indicated 'at 54, and tapers in the cooperating direction.

FIGURE 7 discloses a construction similar to FIG- URE 6 wherein the cooperating interior surface of the ring and exterior surface of the drilling bit are frustoconical. However, the surface of the ring converges upwardly, as indicated at 56, as does the surface of the drilling bit, as indicated at 58.

FIGURE 8 discloses a configuration which is a combination of that disclosed in FIGURE 6 and FIGURE 7. More specifically, the interior surface of the ring 40 includes upper and lower portions which are frusto-conical and taper in opposite directions, the upper portions converging upwardly and the lower portions converging downwardly, as indicated at 60 and 62. The cooperating exterior surface of the drilling bit is similarly tapered, as indicated at 64 and 66.

FIGURE 9 illustrates a configuration which is a substantial reversal of the configuration illustrated in FIG- URE 8. That is, a double frusto-oonical configuration is employed, but the upper part of the interior ring surface diverges upwardly, as indicated at 68, while the lower portion diverges downwardly, as indicated at 70. The cooperating surface of the ring receiving portion of the drilling bit tapers in a corresponding manner, as indicated at 72 and 74.

FIGURE 10 illustrates a configuration which is substantially the reversal of that illustrated in FIGURE 5. As shown, the interior surface of the ring 40 is provided with an annular ridge 76. The corresponding surface of the ring receiving portion of the drilling bit is provided with a cooperating annular groove 78.

It will be understood that in all modifications described above and illustrated in FIGURES 5-10, the dimensions are such as to permit the ring to be expanded by heat and fitted over the cooperating surfaces on the drilling bit in the manner indicated above in connection with the embodiment illustrated in FIGURES 1-4.

It thus will be seen that the objects of this invention have been fully and effectively accomplished. It will be realized, however, that the foregoing specific embodiment has been shown and described only for the purpose of illustrating the principles of this invention and is subject to extensive change without departure from such principles. Therefore, this invention includes all modifications encompassed within the spirit and scope of the following claims.

I claim:

1. A unitized drilling bit adapted for threaded connection to the lower portion of a drill collar or other drill string member symmetric about a vertical axis and having an internal threaded opening tapering upwardly and inwardly from its lower end, such lower end of the drill collar comprising an annular horizontal surface or shoulder surrounding such opening, such opening and shoulder also being symmetric about such vertical axis, comprising in combination:

(a) a plurality of bit segments having lower cutting portions and upper shank portions symmetric about a vertical bit axis, each shank portion having a periphery including a pair of radial surfaces defined by planes passing through said bit axis and a downwardly diverging tapering outer surface, said bit segments being disposed with their cutting portions downward and with the radial surfaces of their shank portions in abutting contact to define a circumferentially complete frusto-conical shank having a tapered and threaded outer surface and a ring receiving shoulder adjacent and below said threaded surface and having a horizontal annular surface and a generally vertical annular surface, said surfaces being symmetric about said vertical bit axis, said threaded and tapered outer shank surface being adapted for coaxial engagement with the corresponding threaded and tapered inner surface of said drill collar, and

(b) a shrink ring disposed in said ring receiving shoulder, seated on the horizontal surface thereof and forcibly engaging the generally vertical surface thereof, said shrink ring having a uniform axial dimension gaged with respect to the axial distance between said shank threads and said horizontal shoulder surface so that the upper surface of the ring accurately defines a make-up surface for tightly engaging said annular shoulder at the lower end of said drill collar when said shank is completely engaged therewith in threaded relationship.

2. The drilling bit of claim 1 in which the generally vertical surface of said shoulder and the corresponding surface of said shrink ring are cylindrical.

3. The drillingbit of claim 1 in which the generally vertical surface of said shoulder and the corresponding surface of said shrink ring are frusto-conical.

4. The drilling bit of claim 1 in which the generally vertical surface of said shoulder and the corresponding surface of said shrink ring include upper and lower frustoconical surfaces inclined in opposite directions with respect 1110 each other.

5. The drilling bit of claim 1 in which the generally vertical surface of said shoulder includes a groove portion and the corresponding surface of said shrink ring includes a ridge portion engaging said groove.

6. The drilling bit of claim 1 in which the generally vertical surface of said shoulder includes a ridge portion and the corresponding surface of said shrink ring includes a groove portion engaging said ridge.

7. In a unitized drilling bit composed of segments each having a lower cutting portion and an upper shank portion defining a portion of a frustum of a cone or a frustoconical shell having a downwardly diverging outer surface, such segments being thus disposed to define a complete shank with a continuous, downwardly diverging outer surface, such segments as thus disposed being provided with threads on the tapered shank surface and a shoulder adjacent and below said shank including an annular surface transverse the vertical axis, such threaded and tapered surface being adapted to engage a correspondingly tapered and threaded surface in the lower end of a drill collar or other drill string member and said shoulder surface being adapted to engage a corresponding annular shoulder surface on the end of such drill collar to provide a tight fit therewith when the pair of threaded surfaces are completely engaged, such bit having been u-nitized heretofore by weld-ing such segments together prior to machining such shank threads and such shoulder surface having been thereafter precisely machined to provide an accurate axial dimension between the shank threads and such shoulder surface corresponding to the like dimension bet-ween the threads and shoulder surface of such drill collar so that tight fits between S such threaded surfaces and such shoulder surfaces can be accomplished substantially simultaneously: the improvement comprising (a) an annular, generally vertical surface on said bit shoulder adjacent the transverse surface thereof and disposed between said transverse surface and said threaded shank, and

(b) a shrink ring disposed in said shoulder, seated on the transverse surface thereof and forcibly engaging the generally vertical surface thereof, said shrink ring having a uniform axial dimension such that the axial distance between its upper surface and said shank threads corresponds to the like dimension between said shoulder and threads of said drill collar, whereby the welding together of said bit segments and the precision machining of said transverse shoulder surface are unnecessary.

8. In a unitized drilling bit of the type described in claim 7, :the improvement therein claimed in which the generally vertical surface of said shoulder and the corresponding surface of said shrink ring are cylindrical.

9. In a unitized drilling bit of the type described in claim 7, the improvement therein claimed in which the generally vertical surface of said shoulder and the corresponding surface of said shrink ring are frusto-conical.

10. In a unitized drilling bit of the :type described in claim 7, the improvement therein claimed in which the generally vertical surface of said shoulder and the corresponding surface of said shrink ring include frustoconical surfaces inclined in opposite directions with respect to each other.

11. In a unitized drilling bit of the type described in claim 7, the improvement therein claimed in which the generally vertical surface of said shoulder includes a groove portion and the corresponding surface of said shrink ring includes a ridge portion engaging said groove. 12. In a unitized drilling bit of the type described in claim 7, the improvement therein claimed in which the generally vertical surface of said shoulder .includes a ridge portion and the corresponding surface of said shrink ring includes a groove portion engaging said ridge.

References Cited in the file of this patent UNITED STATES PATENTS 387,680 Gourley et al Aug. 14, 1888 1,428,122 Smith Sept. 5, 1922 2,209,079 Gilrnan July 23, 1940 2,226,655 Beavan Dec. 31, 1940 2,620,686 Peter Dec. 9, 1952 2,656,153 White Oct. 20, 1953 2,666,622 Hawthorne Jan. 19, 1954 2,688,264 Rudquist Sept. 7, 1954 2,855,181 Olsen Oct. 7, 1958 3,011,557 Conrad Dec. 5, 1961 

